演色性指数

演色性指数（英语：color rendering index; CRI），或叫做显色指数，是一种描述光源呈现真实物体颜色能力的量值。光源的演色性越高，其颜色表现就越接近理想光源或自然光。重视色彩表现的行业，如新生儿护理（英语：Neonatal nursing）、摄影、电影摄影等，一般都偏爱CRI较高的光源。^[1] 国际照明委员会的定义如下：^[2]

演色性：光源对物体造成的颜色效果相较于参考光源的特性，由有意识的或无意识的观察得出。

一个光源的演色性指数，CRI不直接表示一个光源表现的颜色（颜色是与相关色温有关）。演色性取决于光源的光谱。白炽灯有连续的光谱；萤光灯则是离散的线光谱，因此白炽灯拥有较高的演色性指数。

通常在照明商品上标示的"演色性指数"其实以CIE R_a来称呼比较合适。"CRI"是比较广义的说法，而CIE R_a则是国际标准演色性指数（英语：international standard color rendering index）。

理论上，CIE R_a上限为100，定义为标准化日光或者黑体（白炽灯是有效黑体）。有些光源会有负值，例如低压钠灯。萤光灯则分布在大约50（基本型）到98（复磷型）。典型的LED则有80以上，甚至有些制造商宣称可以达到CRI 98。^[3]

CIE R_a在其预测外观颜色的能力上备受质疑，因为量测方式是基于外观颜色模型（英语：color appearance models，如CIECAM02，以及日光模拟器所用的 CIE 异色性指数）。^[4] CRI在视觉评估上不是好的指标，特别是当色温低于5000 开尔文 (K)。^[5]^[6] 一些新的标准，如 IES TM-30，解决了这些问题并逐渐取代专业光照设计中CRI的应用。^[7] 不过CRI仍然常用于家用照明产品的标示。

参考资料编辑

^ Compare these images of a color chart taken under one light source with CRI 70 and another with CRI 85. Lightingdesignlab.com. [2009-04-16]. （原始内容存档于2012-03-31）.
^ CIE 17.4-1987 International Lighting Vocabulary. （原始内容存档于2010-02-27）.
^ LZC-00GW00 Data Sheet (PDF). ledengin.com. LED ENGIN. March 16, 2015. （原始内容 (PDF)存档于January 5, 2017）.
^ Sándor, Norbert; Schanda, János, Visual colour rendering based on colour difference evaluations, Lighting Research and Technology, September 1, 2006, 38 (3): 225–239, S2CID 109858508, doi:10.1191/1365782806lrt168oa .
Conference version of this article:
Sándor, Norbert; Schanda, János, Visual colour-rendering experiments (PDF), AIC Colour '05: 10th Congress of the International Colour Association, 2005: 511–514, （原始内容 (PDF)存档于2011-07-21）
^ Guo, Xin; Houser, Kevin W., A review of colour rendering indices and their application to commercial light sources, Lighting Research and Technology, 2004, 36 (3): 183–199, S2CID 109227871, doi:10.1191/1365782804li112oa
^ CIE, Method of Measuring and Specifying Colour Rendering Properties of Light Sources, Publication 13.3, Vienna: Commission Internationale de l'Eclairage, 1995 [2008-01-19], ISBN 978-3-900734-57-2, （原始内容存档于2008-01-03） (A verbatim re-publication of the 1974, second edition. Accompanying disk D008: Computer Program to Calculate CRIs. 互联网档案馆的存档，存档日期2008-03-27.)
^ Illuminating Engineering Society. 2018. IES Method for Evaluating Light Source Color Rendition, IES Technical Memorandum (TM) 30-18.

[1] Compare these images of a color chart taken under one light source with CRI 70 and another with CRI 85. Lightingdesignlab.com. [2009-04-16]. （原始内容存档于2012-03-31）.

[2] CIE 17.4-1987 International Lighting Vocabulary. （原始内容存档于2010-02-27）.

[3] LZC-00GW00 Data Sheet (PDF). ledengin.com. LED ENGIN. March 16, 2015. （原始内容 (PDF)存档于January 5, 2017）.

[4] Sándor, Norbert; Schanda, János, Visual colour rendering based on colour difference evaluations, Lighting Research and Technology, September 1, 2006, 38 (3): 225–239, S2CID 109858508, doi:10.1191/1365782806lrt168oa .
Conference version of this article:
Sándor, Norbert; Schanda, János, Visual colour-rendering experiments (PDF), AIC Colour '05: 10th Congress of the International Colour Association, 2005: 511–514, （原始内容 (PDF)存档于2011-07-21）

[5] Guo, Xin; Houser, Kevin W., A review of colour rendering indices and their application to commercial light sources, Lighting Research and Technology, 2004, 36 (3): 183–199, S2CID 109227871, doi:10.1191/1365782804li112oa

[CIE1995-6] CIE, Method of Measuring and Specifying Colour Rendering Properties of Light Sources, Publication 13.3, Vienna: Commission Internationale de l'Eclairage, 1995 [2008-01-19], ISBN 978-3-900734-57-2, （原始内容存档于2008-01-03） (A verbatim re-publication of the 1974, second edition. Accompanying disk D008: Computer Program to Calculate CRIs. 互联网档案馆的存档，存档日期2008-03-27.)

[7] Illuminating Engineering Society. 2018. IES Method for Evaluating Light Source Color Rendition, IES Technical Memorandum (TM) 30-18.

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演色性指数

参考资料 编辑

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